Mobile communication terminal, communication system, communication method and control program

ABSTRACT

A mobile communication terminal  10  receives “HCS_PRIO” of a notice data (System Information Block Type  3 ) of a base station  1  or  3 , and determines whether the terminal  10  is present “indoor” and is in “a stationary state or a state moving at a low speed” based on the receiving result. Since there is a high possibility that the terminal  10  is connectable with a wireless LAN when the terminal  10  is present “indoor” and is in “a stationary state or a state moving at a low speed”, the terminal  10  sets a period for monitoring arrival of a beacon signal.

TECHNICAL FIELD

The present invention relates to a mobile communication terminal, and acommunication system, a communication method and a control program usingthereof. Especially, the present invention relates to a WCDMA (widebandcode division multiple access) mobile communication terminal providedwith a wireless LAN (local area network) communication function, and acommunication system, a communication method and a control program usingthereof.

BACKGROUND ART

A WCDMA communication terminal provided with a wireless LANcommunication function is known in recent years. Such a mobilecommunication terminal is connected with a communication network such asinternet through wireless communication with an access point for awireless LAN, which is provided in places such as a station, an airportand a shopping center, to achieve data communication at relatively highspeed. Users are generally satisfactory in many cases in terms ofcommunication cost and communication speed more than communicationservices through WCDMA systems.

Meanwhile, a user of the mobile communication terminal is required tofind out and go to a place where the access point for the wireless LANis provided, and to start wireless LAN communication, if the userdesires to receive benefits of such wireless LAN connection.

In order to allow automatic and prompt data communication throughwireless LAN communication in an area where the wireless LANcommunication is available, rather than starting the wireless LANcommunication in response to an instruction from the user, the arrivalof a so-called beacon signal transmitted from an access point forwireless LAN needs to be monitored constantly by the mobilecommunication terminal.

However, there is a problem of increased power consumption for constantmonitoring. Therefore, it becomes important to efficiently monitor thearrival of a so-called beacon signal transmitted from the access pointfor wireless LAN.

By the way, as stated above, the access point for wireless LAN is oftenprovided in places such as a station, an airport and a shopping center,or “indoors”. Furthermore, an area where communication with the accesspoint for wireless LAN is possible is relatively narrow with a radius ofseveral tens to 200 meters. Therefore, when moving at high speed, themobile communication terminal has a low possibility of detecting thebeacon signal transmitted from the access point for wireless LAN ortends to go beyond a communicable area of the access point soon evenafter detecting the beacon signal. In either case, it is difficult toreceive wireless LAN service.

Considering the above two points, whether a wireless LAN connection ispossible is divided into the following cases:

1) When the Mobile Communication Terminal is Stationary or Moving at aLow Speed:

It is highly probable to achieve the wireless LAN connection as long asthe mobile communication terminal is present indoors. However, aprobability of achieving the wireless LAN connection is low if themobile communication terminal is present outdoors.

2) When the Mobile Communication Terminal is Moving at a High Speed:

There is a low probability of achieving the wireless LAN connection inboth cases that the mobile communication terminal is present indoors andoutdoors.

In this way, whether or not the wireless LAN connection can be achievedis dependent on conditions (i.e. position and speed) of the mobilecommunication terminals.

Japanese Patent Application Publication (JP-P2005-080071A) discloses amobile communication terminal. The mobile communication terminalmeasures a position thereof by GPS (global positioning system) makes adetermination to search an access point of for wireless LAN when themobile communication terminal approaches the wireless LAN access point.

Japanese Patent Application Publication (JP-P2003-169011A) discloses amobile communication terminal. At the time of waiting and receiving twokinds of signals with frequencies f1 and f2, the mobile communicationterminal changes a period to receive the signal with the frequency f2which differs from the signal with the predetermined frequency f1 inaccordance with a moving speed of the mobile communication terminal.

Japanese Patent Application Publication (JP-P2003-309571A) discloses awireless LAN system. According to this technique, a wireless terminalreceives a beacon signal from an access points in a predeterminedperiod.

Japanese Patent Application Publication (JP-P2003-318915A) discloses aninformation processing apparatus. The information processing apparatusdetermines whether it is present indoors or outdoors by a power sourcesupplied from an AC adapter or a battery.

Japanese Patent Application Publication (JP-P2005-260987A) discloses acommunication system. According to this conventional technique, acommunication control section of a base station sets a period totransmit a beacon signal on the basis of a setting request received froma terminal station.

Japanese Patent Application Publication (JP-P2001-95063A) discloses awireless receiver driven with a battery. The wireless receiverdetermines whether a transmission signal transmitted from a wirelesstransmitter non-periodically is present in accordance with apredetermined intermittent period. The wireless receiver changes theintermittent period in accordance with a usage state.

Japanese Patent Application Publication (JP-P2002-190769A) discloses amobile communication apparatus. The mobile communication apparatusdetects a reception level in order to determine whether or not themobile communication apparatus is moving on the basis of variationhistory of the detected reception level.

There is also a paper “3GPP TS25.304 V5.3.0 (2003-06)” which discloses atechnique to execute a switching process from a cell, where a mobilecommunication terminal receives services during moving at present toanother cell by using data for HCS (hierarchical cell configuration).

DISCLOSURE OF INVENTION

According to communication systems in related art, the arrival of abeacon signal is constantly monitored regardless that whether thewireless LAN connection is possible is dependent on conditions (i.e.position and speed) of the mobile communication terminal. Therefore,power consumption increases in the mobile communication terminal.

Therefore, an objective of the present invention is to provide a mobilecommunication terminal which can monitor the arrival of a beacon signaltransmitted from an access point for wireless LAN more efficiently thanin the related arts, and a communication system, a communication methodand a control program using the same.

The mobile communication terminal according to the present invention cancommunicate with a first base station, a second base station and awireless LAN access point, respectively. The second base station ispresent within a service area of the first base station, having aservice area which is smaller than that of the first base station. Thewireless LAN access point is present within the service area of thesecond base station. The mobile communication terminal according to thepresent invention includes a determining section and a changing section.The determining section receives a specific signal transmitted from thefirst or second base station and determines whether or not it is highlyprobable for the mobile communication terminal itself to be connected tothe wireless LAN access point, in accordance with the reception result.The changing section changes a period to monitor the arrival of thebeacon signal transmitted from the wireless LAN access point on thebasis of the determination results obtained from the determiningsection.

A communication system according to the present invention includes afirst base station, a second base station, a wireless LAN access pointand a mobile communication terminal. The second base station is presentwithin a service area of the first base station, having a service areawhich is smaller than that of the first base station. The wireless LANaccess point is present within the service area of the second basestation. The mobile communication terminal can communicate with thesefirst and second base stations and the wireless LAN access point. Themobile communication terminal includes a determining section and achanging section. The determining section receives a specific signaltransmitted from the first or second base station and determines whetheror not it is highly probable for the mobile communication terminalitself to be connected to the wireless LAN access point in accordancewith the reception result. The changing section changes a period tomonitor the arrival of a beacon signal transmitted from the wireless LANaccess point on the basis of the determination results obtained from thedetermining section.

A communication method according to the present invention is used in acommunication system which includes a first base station, a second basestation, a wireless LAN access point and a mobile communicationterminal. The second base station is present within a service area ofthe first base station, having a service area which is smaller than thatof the first base station. The wireless LAN access point is presentwithin the service area of the second base station. The mobilecommunication terminal can communicate with these first and second basestations and the wireless LAN access point. The communication methodaccording to the present invention includes: (A) the mobilecommunication terminal receiving a specific signal transmitted from thefirst or second base station and determining whether or not it is highlyprobable for the terminal itself to be connected to the wireless LANaccess point in accordance with the reception result; and (B) the mobilecommunication terminal changing a period to monitor the arrival of thebeacon signal transmitted from the wireless LAN access point on thebasis of the determination result obtained in the above determinationstep.

A control program according to the present invention is provided for acommunication method used in a communication system which includes afirst base station, a second base station, a wireless LAN access pointand a mobile communication terminal. The second base station is presentwithin a service area of the first base station, having a service areawhich is smaller than that of the first base station. The wireless LANaccess point is present within a service area of the second basestation. The mobile communication terminal can communicate with thesefirst and second base stations and the wireless LAN access point. Thecontrol program according to the present invention is stored in themobile communication terminal. The control program causes a computer toexecute: (A) receiving a specific signal transmitted from the first orsecond base station and determining whether or not it is highly probablefor the mobile communication terminal itself to be connected to thewireless LAN access point in accordance with the reception result; and(B) the mobile communication terminal changing a period to monitor thearrival of the beacon signals transmitted from the wireless LAN accesspoint on the basis of the determination results obtained in the abovedetermination step.

Next, effects of the present invention will be described. In the presentinvention, characteristics of the wireless LAN access point as stated inthe above 1) and 2) are considered to determine whether a probability ofachieving the wireless LAN connection is high or low, followed bychanging a period to monitor the arrival of so-called beacon signalstransmitted from the wireless LAN access point. More specifically, aperiod to monitor the arrival of the beacon signals is made shorter whenit is determined that a probability of achieving the wireless LANconnection is high, as opposed to extend a period to monitor the arrivalof the beacon signals (or discontinue the monitoring) when theprobability of achieving the wireless LAN connection is determined to below.

Therefore, reduction of power spent for monitoring the beacon signalsfrom the wireless LAN access point can be compatible with usability ofexecuting data communication through the wireless LAN by detecting thewireless LAN access point promptly in an area where the wireless LANconnection is available.

According to the present invention, the arrival of the beacon signalstransmitted from the access point for the wireless LAN can be monitoredmore efficiently than conventional techniques owing to include theaforementioned configuration.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a conceptual diagram showing an example of a configuration ofthe communication system according to the present invention;

FIG. 2 is a block diagram showing an example of a configuration ofmobile communication terminal according to the present invention; and

FIG. 3 is a flowchart showing an example of the communication methodaccording to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

Hereinafter, a mobile communication terminal of the present invention,and a communication system, a communication method and control programusing the same will be described with reference to the attacheddrawings.

First Exemplary Embodiment

FIG. 1 shows an example of a configuration of a communication systemaccording to the present invention. In FIG. 1, the communication systemincludes a WCDMA base station 1, a service area (outdoor) 11 of theWCDMA base station 1, a mobile communication terminal (stationary) 10 aand a mobile communication terminal (moving at high speed) 10 b whichare present in the service area 11, a building 2 provided in the servicearea (outdoor) 11, a WCDMA base station 3 provided in the building 2; aservice area (indoor) 20 of the WCDMA base station 3, a wireless LANaccess point 4 provided in the service area (indoor) 20, a service area(indoor) 30 of the wireless LAN access point 4, a mobile communicationterminal (moving at high speed) 10 c which is present in the servicearea (indoor) 20, and a mobile communication terminal (stationary) 10 dwhich is present in the service area (indoor) 30.

FIG. 1 shows, as one exemplary embodiment of the present invention, theWCDMA base station 1 provided outdoors, the WCDMA base station 3provided indoors, the wireless LAN access point 4 provided indoors, andthe mobile communication terminals 10 a to 10 d which are present withinthe respective service areas.

The mobile communication terminal 10 a is present in the service area(outdoor) 11 of the WCDMA base station 1 and stationary.

The mobile communication terminal 10 b is present in the service area(outdoor) 11 of the WCDMA base station 1 and moving at high speed.

The mobile communication terminal 10 c is present in the service area(indoor) 20 of the WCDMA base station 3 and moving at high speed.

The mobile communication terminal 10 d is present in the service area(indoor) 30 of the wireless LAN access point 4 and stationary.

Therefore, according to the characteristics of the wireless LAN accesspoint indicated in the above 1) and 2), only the mobile communicationterminal 10 d has a high probability of achieving a wireless LANconnection.

Next, an example of the configuration of the mobile communicationterminal 10 will be described. FIG. 2 is a block diagram showing theconfiguration of the mobile communication terminal 10 according to thepresent invention. In FIG. 2, the mobile communication terminal 10(i.e., 10 a to 10 d) is provided with radio sections 41 and 42, antennas43 and 44, a control section 45 and a main body storage section 46. Themobile communication terminal 10 may also be further provided with a GPSpositioning section 60.

The radio sections 41 and 42, the storage section 46 and the GPSpositioning section 60 are connected to the control section 45. Theantenna 43 is connected to the radio section 41 and the antenna 44 isconnected to the radio section 42. The radio section 41 corresponds to aWCDMA system, and the radio section 42 corresponds to a wireless LANsystem.

The storage section 46 stores a program and data required to realizecontrol by the control section 45. The control section 45 controls theradio sections 41 and 42 and the storage section 46. The control section45 also includes a determining section 51 and a changing section 52.

Next, a method of determining whether the mobile communication terminal10 (i.e., 10 a to 10 d) is present indoors or outdoors will bedescribed. The method corresponds to the method described in thedocument 3GPP TS25.304 V5.3.0 (2003-06). The determination is made bythe determining section 51 of the control section 45.

The mobile communication terminal 10 receives a parameter “HCS_PRIO”included in a notice data (i.e. system information block type 3) from abase station from which the services are received at present. When theparameter “HCS_PRIO” exhibits a value equals to or larger than a certainthreshold value (e.g. in case of the WCDMA base station 3 shown in FIG.1), the mobile communication terminal 10 receives the services from abase station whose cover area is relatively small as in an area within abuilding (e.g. building 2). Accordingly, the determining section 51 ofthe control section 45 determines the mobile communication terminal 10is present “indoors”.

In contrast, if the parameter “HCS_PRIO” whose value is less than acertain threshold value (e.g. in case of the WCDMA base station 1 shownin FIG. 1), the mobile communication terminal 10 receives the servicesfrom a base station having a relatively large cover area. Accordingly,the determining section 51 of the control section 45 determines themobile communication terminal 10 is present “outdoors”.

The HCS function described in the document 3GPP TS25.304 V5.3.0(2003-06) can also be similarly used in a method of determining whetherthe mobile communication terminal 10 (i.e. 10 a to 10 d) is “stationaryor moving at low speed” or “moving at high speed”. That is, a“high-mobility state” (which is a state where cell reselection isgenerated for N_CR times within a time period of T_CRmax) is determinedas “moving at high speed”. Other cases (i.e. in a state where cellreselection is not observed for N_CR times within a time period ofT_CRmax+T_CRmaxHyst) are determined as “stationary or moving at lowspeed”.

HCS is described in the above-stated document 3GPP TS25.304 V5.3.0(2003-06). In the above “high-mobility state”, the mobile communicationterminal selects a base station having low “HCS_PRIO” (which isgenerally allocated to a base station whose cover area is large) withpriority. In contrast, the mobile communication terminal selects a basestation having large “HCS_PRIO” (which is generally allocated to a basestation whose cover area is small) with priority in cases other than the“high-mobility state”. That is, the frequency of having cell reselectioncan be suppressed by selecting a base station having a large cover areawhen the mobile communication terminal is moving at high speed. In casesother than moving at high speed, it is allowed to select base stationshaving a small cover area such as within a building.

It should be noted “HCS_PRIO”, “T_CRmax”, “T_CRmaxHyst” and “N_CR”,which are parameters used in HCS, are notified to the mobilecommunication terminal 10 by the notice data (i.e. system informationblock type 3) from the base station. It should be also noted that “cellreselection” means moving from a cell, from which the mobilecommunication terminal receive services at present, to another cell.

The determining section 51 of the control section 45 determines acurrent state (i.e. position and speed) of the terminal 10 itself byWCDMA communication using the radio section 41. The changing section 52of the control section 45 changes a period to monitor an arrival of abeacon signal received through the wireless LAN by using the radiosection 42 on the basis of the determination result.

According to the first exemplary embodiment of the present invention,the mobile communication terminal 10 determines whether a probability ofachieving the wireless LAN connection is high or low based on the dataobtained in the WCDMA system. The mobile communication terminal 10further determines a period to monitor the arrival of so-called beaconsignal transmitted from the wireless LAN access point on the basis ofthe determination result. As a result, the wireless LAN access point canbe promptly detected in an area where the probability of achieving thewireless LAN connection is high, whereby data communication through thewireless LAN can be performed. In contrast, in an area where theprobability of achieving the wireless LAN connection is low, power spentfor monitoring the beacon signal transmitted from the wireless LANaccess point can be reduced.

In the first exemplary embodiment, whether the mobile communicationterminal 10 is present “indoors” or “outdoors” and whether it is“stationary or moving at low speed” or “moving at high speed” aredetermined by using a method based on the WCDMA standard (refer to thedocument 3GPP TS25.304). Accordingly, it is not necessary to add newbase station parameters, make 3GPP functional changes and add newdevices to the terminal for the purpose of these determinations.

FIG. 3 is a flowchart showing an example of a communication methodaccording to the first exemplary embodiment of the present invention. Itis assumed that the control section 45 of the mobile communicationterminal 10 monitors the arrival of so-called beacon signal receivedfrom the wireless LAN access point by using the radio section 42 in aT_WLAN period of a timer (not shown).

First, the control section 45 controls the radio section 41 to receivenotice data (i.e. system information block type 3) transmitted from theWCDMA base station from which services are received at present in orderto receive various kinds of parameters including “HCS_PRIO”, “T_CRmax”,“T_CRmaxHyst” and “N_CR” (step S1).

Next, the determining section 51 of the control section 45 determineswhether or not the mobile communication terminal 10 is in the“high-mobility state” (i.e. moving at high speed) by the methoddescribed in the aforementioned document (3GPP TS25.304) (step S2). Morespecifically, the determining section 51 of the control section 45monitors a frequency of cell reselection within unit time (T_CRmax). Ifthe frequency exceeds N_CR times, the determining section 51 determinesthat the mobile communication terminal is in the “high-mobility” state(i.e. moving at high speed) (step S2: Yes). In contrast, if cellreselection is not observed for N_CR times within the unit time(T_CRmax+T_CRmaxHyst), the determining section 51 determines that themobile communication terminal is not in the “high-mobility state” (i.e.not moving at high speed but stationary or moving at low speed) (stepS2: No).

If the determining section 51 determines that the terminal 10 itself ismoving at high speed (step S2: Yes), the terminal 10 itself has a lowprobability of detecting the beacon signal transmitted from the wirelessLAN access point 4 or tends to go beyond a communicable area of thewireless LAN access point 4 soon after detecting the beacon signal. Fromthis reason, the changing section 52 of the control section 45 sets theaforementioned period T_WLAN of the timer to a relatively large value(e.g. 1 minute) (step S3).

Meanwhile, if the determining section 51 determines that the terminal 10itself is not moving at high speed (step S2: No), the determiningsection 51 compares “HCS_PRIO” of the WCDMA base station, from whichservices are received at present, with a threshold value (referred to as“P_Th” hereinafter) (step S4).

If “HCS_PRIO” exhibits a value which is less than “P_Th” (step S4:HCS_PRIO<P_Th), the determining section 51 determines the WCDMA basestation, from which services are received at present, has a largeservice area (i.e. the terminal 10 itself is present outdoors). In thiscase, the terminal 10 has a low probability of detecting the beaconsignal transmitted from wireless LAN access point which is oftenprovided indoors. From this reason, the changing section 52 of thecontrol section 45 sets the aforementioned period T_WLAN of the timer toa relatively large value (e.g. one minute) (step S5).

In contrast, if “HCS_PRIO” exhibits a value which is equal to or longerthan P_Th (step S4: HCS_PRIO•P_Th), the determining section 51determines that a WCDMA base station, from which services are receivedat present, has a small service area (i.e. the terminal 10 itself ispresent indoors). In this case, it is highly probable that the terminal10 itself detects the beacon signal transmitted from the wireless accesspoint which is often provided indoors. From this reason, the changingsection 52 of the control section 45 sets the aforementioned periodT_WLAN of the timer to a relatively small value (e.g. 10 seconds) (stepS6).

In this way, the method of controlling the mobile communication terminalaccording to the present invention includes the steps of: determiningwhether a probability of achieving the wireless LAN connection is highor low on the basis of data obtained from a WCDMA system through whichservices are received; and determining a period to monitor the arrivalof beacon signal transmitted from the wireless LAN access point on thebasis of the determination result. The process according to the presentexemplary embodiment is therefore realized and the aforementionedeffects can be obtained.

Second Exemplary Embodiment

In the communication system according to a second exemplary embodimentof the present invention, a GPS function is used to determine whetherthe mobile communication terminal 10 is present “indoors” or “outdoors”.That is, the mobile communication terminal 10 includes the GPSpositioning section 60 which is controlled by the control section 45.The GPS positioning section 60 receives position measurement signalstransmitted from a plurality of GPS satellites. The control section 45calculates a current position of the terminal 10 itself on the basis ofthese signals.

In the present exemplary embodiment, instead of calculating a currentposition of the terminal 10 itself from the position measurementsignals, whether the terminal 10 is present “indoors” or “outdoors” isdetermined from the number of GPS satellites captured by the GPSpositioning section 60 at present. More specifically, if the number ofcaptured GPS satellites is equal to or less than a predetermined number,the determining section 51 of the control section 45 determines that theterminal 10 itself entered “indoors”. In contrast, if the number ofcaptured GPS satellites exceeds the predetermined number, thedetermining section 51 determines that the terminal 10 itself went“outdoors”. On the basis of these determinations, the changing section52 of the control section 45 changes a period to monitor the beaconsignal transmitted from the wireless LAN access point.

According to the present exemplary embodiment, whether the terminal 10itself is present “indoors” or “outdoors” is determined by using the GPSsatellites. Positional data of the terminal obtained from GPS satellitesis not used here. That is, the present exemplary embodiment differs froma technique disclosed in Japanese Patent Application Publication(JP-P2005-080071A) in which whether a terminal is present close to thewireless LAN access point is determined from a position of the terminalobtained from GPS satellites and a position of the wireless LAN accesspoint stored in advance and wireless LAN searching is performed if theterminal is close to the wireless LAN access point. According to thepresent exemplary embodiment, the effects can be obtained that the dataon the position of the wireless LAN access point does not need to beknown in advance.

Moreover, when no signal from GPS satellites can be received, it isdetermined that the terminal entered “indoors”. Therefore, the presentinvention can be applied to indoor usage in which signals from GPSsatellites are unreachable, which differs from the invention disclosedin the aforementioned Japanese Patent Application Publication(JP-P2005-080071A).

Third Exemplary Embodiment

In the communication system according to a third exemplary embodiment ofthe present invention, whether the mobile communication terminal 10 ispresent “indoors” or “outdoors” is determined on the basis of ascrambling code used by a WCDMA base station (i.e. WCDMA base station 3shown in FIG. 1) provided in the vicinity of an area in whichcommunication with the wireless LAN access point 4 is available. Morespecifically, a scrambling code used by the WCDMA base station 3 is setto a specific one, and if a base station (i.e. WCDMA base station 3)using this scrambling code is detected, the control section 45determines that the terminal 10 itself is present “indoors”.

In contrast, the control section 45 determines that the terminal 10 ispresent “outdoors” as long as the base station (i.e. WCDMA base station3) using this scrambling code is not detected.

It should be noted that the specific scrambling code can bedistinguished by using, for example, “code group of 60 to 64” and“primary code number of 7 to 8” or the like in (primary) scramblingcodes used in base stations. It should be noted that this method needsto correspond to both the base station 3 and the mobile communicationterminal 10. That is, recognition of scrambling codes used in both ofthem needs to be adjusted in advance.

According to the present exemplary embodiment, a scrambling code of theWCDMA base station can be used to determine whether the mobile phone ispresent “indoors” or “outdoors”.

Fourth Exemplary Embodiment

In the communication system according to a fourth exemplary embodimentof the present invention, whether the mobile communication terminal 10is present “indoors” or “outdoors” is determined on the basis of asignal having a specific frequency to be used by a WCDMA base station(i.e. WCDMA base station 3 shown in FIG. 1) which is provided in thevicinity of a communicable area of the wireless LAN access point 4. Ifthe base station using this frequency is detected, the control section45 determines that the terminal 10 itself is present “indoors”. Morespecifically, the frequency used by the WCDMA base station 3 is set to aspecific one and if the base station using this frequency (i.e. WCDMAbase station 3) is detected, the control section 45 determines that theterminal 10 itself is present “indoors”.

In contrast, the control section 45 determines that the terminal 10itself is present “outdoors” as long as the base station using thisfrequency (i.e. WCDMA base station 3) is not detected.

It should be noted the specific frequency can be distinguished by using,for example, “WCDMA1.7 GHz band” and “UARFCN (which is a numberexpressing a frequency and can be converted to a frequency bymultiplying it by 0.2 times) of 10551 to 10600” or the like infrequencies used by base stations. This method needs to correspond toboth the base station 3 and the mobile communication terminal 10. Thatis, recognition of frequencies used in both of them needs to be adjustedin advance.

According to the fourth exemplary embodiment, a specific frequency usedby the WCDMA base station can be used to determine whether the mobilephone is present “indoors” or “outdoors”.

Fifth Exemplary Embodiment

In the communication system according to a fifth exemplary embodiment ofthe present invention, parameters • and •, which differ from the HCSparameters (i.e. “T_CRmax”, “T_CRmaxHyst” and “N_CR”), are used todetermine whether the mobile communication terminal 10 is “stationary ormoving at low speed” or “moving at high speed”. More specifically, theparameters • and •, which differ from the HCS parameters (i.e.“T_CRmax”, “T_CRmaxHyst” and “N_CR”), are set in the mobilecommunication terminal 10 in advance. Then, if the frequency of havingcell reselection per unit time • is equal to or more than a fixed number•, the control section 45 determines that the terminal 10 itself is“moving at high speed”. In contrast, if the frequency is less than thefixed number •, the control section 45 determines that the terminal 10itself is “stationary or moving at low speed”.

According to the fifth exemplary embodiment, the parameters • and •,which differ from the HCS parameters (i.e. “T_CRmax”, “T_CRmaxHyst” and“N_CR”), can be used to determine whether the mobile phone is“stationary or moving at low speed” or “moving at high speed”.

Sixth Exemplary Embodiment

The parameters • and •, which differ from the HCS parameters (i.e.“T_CRmax”, “T_CRmaxHyst” and “N_CR”), are used in the communicationsystem according to sixth exemplary embodiment of the present inventionin the same manner as the fifth exemplary embodiment in order todetermine whether the mobile communication terminal 10 is “stationary ormoving at low speed” or “moving at high speed”. More specifically, ifthe frequency of having handover (which is a process to change (or movefrom/to) the base station during communication) per the unit time • isequal to or more than the fixed number •, the control section 45determines that the terminal 10 itself is “moving at high speed”. Incontrast, if the frequency is less than the fixed number •, the controlsection 45 determines that the terminal 10 itself is “stationary ormoving at low speed”.

The sixth exemplary embodiment makes it possible to use the frequency ofhandover as a determination reference, as opposed to using the frequencyof cell reselection as a determination reference according to the fifthexemplary embodiment.

Seventh Exemplary Embodiment

Next, a seventh exemplary embodiment will be described. Since theaforementioned HCS is a relatively new function, it is considered thatHCS is not applied to many base stations in practical use. That is, theparameters related to HCS are not yet entered to notice data of basestations in many cases. Therefore, when services are received from thebase stations to which HCS is applied, whether the mobile terminal ispresent “indoors” or “outdoors” and whether the mobile terminal is“stationary or moving at low speed” or “moving at high speed” aredetermined by the method using the HCS as described in the firstexemplary embodiment. In contrast, when services are received from thebase stations to which HCS is not applied, whether the terminal ispresent “indoors” or “outdoors” and whether the terminal is “stationaryor moving at low speed” or “moving at high speed” are determined by amethod in which HCS described in the second to sixth exemplaryembodiments is not used.

According to a seventh exemplary embodiment, the present invention isapplicable to both of base stations with application of HCS and withoutapplication of HCS.

Eighth Exemplary Embodiment

In the already provided exemplary embodiments, the period T_WLAN of thetimer is set to a relatively large value (e.g. one minute) in an areahaving a low probability of achieving the wireless LAN connection (referto steps S3 and S5 shown in FIG. 3). This period T_WLAN may also be setto infinite value. In this case, the system is operated in such a mannerthat the beacon signal transmitted from the wireless LAN access point isnot monitored in the area having the low probability of achieving thewireless LAN connection because the timer does not expire.

In the already provided exemplary embodiments, the period T_WLAN of thetimer is also set to two kinds of values which are a large value and asmall value (refer to steps S3, S5 and S6 shown in FIG. 3). This periodT_WLAN is not limited to the two kinds. For example, two kinds of P_Th1and P_Th2 are prepared as P_Th for comparison with HCS_PRIO in step S4shown in FIG. 3 (e.g. P_Th1 is smaller than P_Th2). The period T_WLAN ofthe timer is then determined as follows in place of steps S5 and S6.

If HCS_PRIO is smaller than P_Th1, the period T_WLAN of the timer is setto a large value (e.g. one minute) (step S7).

If HCS_PRIO is equal to or larger than P_Th1 and smaller than P_Th2, theperiod T_WLAN of the timer is set to an intermediate value (e.g. 30seconds) (step S8).

If HCS_PRIO is equal to or larger than P_Th2, the period T_WLAN of thetimer is set to a small value (e.g. 10 seconds) (step S9).

Although two kinds of P_Th are used in the above case, three or morekinds of P_Th may also be used.

According to the eighth exemplary embodiment, power consumption can befurther reduced in the mobile communication terminal. Alternatively, theperiod of the timer can be adjusted more finely.

Ninth Exemplary Embodiment

In the already provided exemplary embodiments, the system in which thewireless LAN is combined with the WCDMA system has been described. Thepresent invention is also applicable to a combination with otherwireless systems. For example, the present invention is applicable tothe mobile communication terminal corresponding to the wireless LAN anda GSM (global system for mobile communication) system. Since it isimpossible to apply the method using the HCS to systems other than theWCDMA system, the present exemplary embodiment changes the period T_WLANof the timer according to the methods in which the HCS as described inthe second to seventh exemplary embodiments is not used.

According to a ninth exemplary embodiment, the present invention can beapplied to a combination of the wireless LAN and the GSM system.

Tenth Exemplary Embodiment

Although a combination of two systems including the wireless LAN and theWCDMA system or the wireless LAN and the GSM system has been describedin the already provided exemplary embodiments, the present invention canalso be made to correspond to a combination of three or more systems.For example, the mobile communication terminal corresponding to thewireless LAN, the WCDMA system and the GSM system may also be provided.In a certain moment, a wireless system receiving services is eitherWCDMA or GSM. A wireless system receiving services at this time can beused to change the period T_WLAN of the timer in accordance with any oneof the methods according to the already provided exemplary embodiments.

According to a tenth exemplary embodiment, the present invention isapplicable to a combination of three or more systems.

Eleventh Exemplary Embodiment

In the communication system according to an eleventh exemplaryembodiment of the present invention, a control program for thecommunication method is provided. The storage section 46 of the mobilecommunication terminal 10 stores a program and data required to realizea control by the control section 45. That is, the storage section 46stores a control program to cause a computer (which corresponds to thecontrol section 45) to execute the processes according to the alreadyprovided exemplary embodiments.

The control section 45 reads the control program from the storagesection 46 in order to control the radio sections 41 and 42 inaccordance with the program. Contents of the control are alreadydescribed and the description thereof will be omitted.

In the eleventh exemplary embodiment of the present invention, thecontrol program can be obtained by which effects shown in the alreadyprovided exemplary embodiments can be exhibited.

1. A mobile communication terminal which can communicate with a first base station, a second base station which is present within a service area of said first base station, and has a service area which is smaller than that of said first base station, and a wireless LAN access point, which is present within a service area of said second base station, said mobile communication terminal comprising: a determining section configured to receive a specific signal transmitted from said first or second base station and to determine whether or not there is a high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on a reception result; and a changing section configured to change a period to monitor arrival of a beacon signal transmitted from said wireless LAN access point based on the determination result of said determining section.
 2. The mobile communication terminal according to claim 1, wherein said determining section acquires a data of a current position and current moving speed of said mobile communication terminal from the specific signal and determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on the data.
 3. The mobile communication terminal according to claim 1, wherein said first and second base stations are base stations of a WCDMA (wideband Code Division Multiple Access) system.
 4. The mobile communication terminal according to claim 1, wherein the specific signal is a predetermined parameter of a notice data.
 5. The mobile communication terminal according to claim 4, wherein the notice data is a System Information Block Type 3, and the predetermined parameter is HCS_PRIO.
 6. The mobile communication terminal according to claim 1, wherein said mobile communication terminal comprises a GPS (Global Positioning System) positioning section, and said determining section determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on whether a number of GPS satellites captured by said GPS positioning section is equal to or less than a threshold.
 7. The mobile communication terminal according to claim 1, wherein the specific signal which is transmitted from said second base station is a Scrambling Code signal.
 8. The mobile communication terminal according to claim 1, wherein the specific signal which is transmitted from said second base station is a signal with a specific frequency.
 9. The mobile communication terminal according to claim 1, wherein the specific signal is a signal of data indicating a number of times of Cell Reselection by said mobile communication terminal.
 10. The mobile communication terminal according to claim 1, wherein the specific signal is a signal of data indicating a number of times of Handover of said mobile communication terminal.
 11. The mobile communication terminal according to claim 1, wherein said first and second base stations are base stations of a GSM (Global system Mobile Communication) system.
 12. A communication system comprising a mobile communication terminal which can communicate with a first base station, a second base station which is present within a service area of said first base station, and has a service area which is smaller than that of said first base station, and a wireless LAN access point, which is present within a service area of said second base station, wherein said mobile communication terminal comprises: a determining section configured to receive specific signals transmitted from said first base station or said second base station and to determine whether or not there is a high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on a reception result; and a changing section configured to change a period to monitor arrival of a beacon signal transmitted from said wireless LAN access point based on the determination result of said determining section.
 13. The communication system according to claim 12, wherein said determining section acquires a data of a current position and current moving speed of said mobile communication terminal from the specific signal and determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on the data.
 14. The communication system according to claim 12, wherein said first and second base stations are base stations of a WCDMA (wideband Code Division Multiple Access) system.
 15. The communication system according to claim 12, wherein the specific signal is a predetermined parameter of a notice data.
 16. The communication system according to claim 15, wherein the notice data is a System Information Block Type 3, and the predetermined parameter is HCS_PRIO.
 17. The communication system according to claim 12, wherein said mobile communication terminal comprises a GPS (Global Positioning System) positioning section, and said determining section determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on whether a number of GPS satellites captured by said GPS positioning section is equal to or less than a threshold.
 18. The communication system according to claim 12, wherein the specific signal which is transmitted from said second base station is a Scrambling Code signal.
 19. The communication system according to claim 12, wherein the specific signal which is transmitted from said second base station is a signal with a specific frequency.
 20. The communication system according to claim 12, wherein the specific signal is a signal of data indicating a number of times of Cell Reselection by said mobile communication terminal.
 21. The communication system according to claim 12, wherein the specific signal is a signal of data indicating a number of times of Handover of said mobile communication terminal.
 22. The communication system according to claim 12, wherein said first and second base stations are base stations of a GSM (Global system Mobile Communication) system.
 23. A communication method in a communication system comprising a mobile communication terminal which can communicate with a first base station, a second base station which is present within a service area of said first base station, and has a service area which is smaller than that of said first base station, and a wireless LAN access point, which is present within a service area of said second base station, said communication method comprising: (A) receiving a specific signal transmitted from said first or second base station and determining whether or not there is a possibility that said mobile communication terminal is connected to a wireless LAN access point, based on the reception results; and (B) changing a period to monitor arrival of a beacon signal transmitted from said wireless LAN access point based on the determination result in said determination (A).
 24. The communication method according to claim 23, wherein in said (A), said mobile communication terminal acquires a data of a current position and current moving speed of said mobile communication terminal from the specific signal and determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on the data.
 25. The communication method according to claim 23, wherein said first and second base stations are base stations of a WCDMA (wideband Code Division Multiple Access) system.
 26. The communication method according to claim 23, wherein the specific signal is a predetermined parameter of a notice data.
 27. The communication method according to claim 26, wherein the notice data is a System Information Block Type 3, and the predetermined parameter is HCS_PRIO.
 28. The communication method according to claim 23, wherein In said (a), said mobile communication terminal determines whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on whether a number of GPS satellites captured by said GPS positioning section is equal to or less than a threshold.
 29. The communication method according to claim 23, wherein the specific signal which is transmitted from said second base station is a Scrambling Code signal.
 30. The communication method according to claim 23, wherein the specific signal which is transmitted from said second base station is a signal with a specific frequency.
 31. The communication method according to claim 23, wherein the specific signal is a signal of data indicating a number of times of Cell Reselection by said mobile communication terminal.
 32. The communication method according to claim 23, wherein the specific signal is a signal of data indicating a number of times of Handover of said mobile communication terminal.
 33. The communication method according to claim 23, wherein said first and second base stations are base stations of a GSM (Global system Mobile Communication) system.
 34. A software medium stored with a computer-readable code for a control program for a communication method in a communication system comprising a mobile communication terminal which can communicate with a first base station, a second base station which is present within a service area of said first base station, and has a service area which is smaller than that of said first base station, and a wireless LAN access point, which is present within a service area of said second base station, said control program stored in said mobile communication terminal, and making a computer to execute: (A) receiving a specific signal transmitted from said first or second base station and determining whether or not there is a possibility that said mobile communication terminal is connected to a wireless LAN access point, based on the reception results; and (B) changing a period to monitor arrival of a beacon signal transmitted from said wireless LAN access point based on the determination result in said determination (A).
 35. The software medium according to claim 34, wherein said (A) comprises: acquiring a data of a current position and current moving speed of said mobile communication terminal from the specific signal; and determining whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on the data.
 36. The software medium according to claim 34, wherein said first and second base stations are base stations of a WCDMA (wideband Code Division Multiple Access) system.
 37. The software medium according to claim 34, wherein the specific signal is a predetermined parameter of a notice data.
 38. The software medium according to claim 37, wherein the notice data is a System Information Block Type 3, and the predetermined parameter is HCS_PRIO.
 39. The software medium according to claim 34, wherein said (A) comprising: determining whether or not there is the high possibility that said mobile communication terminal is connected to said wireless LAN access point, based on whether a number of GPS satellites captured by said GPS positioning section are equal to or less than a threshold.
 40. The software medium according to claim 34, wherein the specific signal which is transmitted from said second base station is a Scrambling Code signal.
 41. The software medium according to claim 34, wherein the specific signal which is transmitted from said second base station is a signal with a specific frequency.
 42. The software medium according to claim 34, wherein the specific signal is a signal of data indicating a number of times of Cell Reselection by said mobile communication terminal.
 43. The software medium according to claim 34, wherein the specific signal is a signal of data indicating a number of times of Handover of said mobile communication terminal.
 44. The software medium according to claim 34, wherein said first and second base stations are base stations of a GSM (Global system Mobile Communication) system. 